JP2021148662A - Measurement device - Google Patents

Abstract

To provide a measurement device that can exert a measurement performance sufficiently, as improving work efficiency.SOLUTION: A measurement device comprises: a conveyance part that can convey articles; a measurement part that measures a weight of the article on the conveyance part; and a control unit that, when the conveyance part is on duty and the article is not conveyed by the conveyance part, puts the conveyance part into an operation at a plurality of conveyance speeds, and selects a corresponding one digital filter of a plurality of digital filters with respect to each of the plurality of conveyance speeds, and stores the selected digital filter.SELECTED DRAWING: Figure 3

Description

The present invention relates to a weighing device.

An example of a weighing device is a device that weighs an article (object to be weighed) conveyed by a conveyor. The following Patent Document 1 describes a measuring unit that outputs an original signal corresponding to the weight of a weighed article, a filter unit that performs filtering processing on the original signal output from the measuring unit, and a waveform of the weighing signal after filtering processing. A weighing device including a control unit for displaying the above on the display unit is disclosed.

Republished Patent WO2015-141670A

In the weighing device as described above, a plurality of digital filters may be preset in the filter unit. As a result, the weight of the article can be accurately weighed by setting a digital filter suitable for the weighing device and its surrounding conditions. Here, for example, the state of the weighing device changes according to a change in the transport speed of the article or the like. Therefore, it is difficult for a mere user of the weighing device to set the digital filter according to the change in the situation of the weighing device. Therefore, when the transport speed of the article by the weighing device changes, the digital filter is usually set by the designer or the expert of the weighing device, or the digital filter suitable for the situation is not set and the weighing device is not set. Only the digital filter set as standard in is used. In the former case, there is a problem that the burden on the designer or the skilled person of the weighing device is heavy and the working efficiency of the weighing device is lowered. In the latter case, the weighing performance of the weighing device may not be sufficiently exhibited.

An object of one aspect of the present invention is to provide a weighing device capable of sufficiently exhibiting weighing performance while improving work efficiency.

The weighing device according to one aspect of the present invention includes a transporting unit capable of transporting articles, a measuring unit for weighing articles on the transporting section, and when the transporting section is in operation and the article is not transported by the transporting section. A control unit that operates the transport unit at a plurality of transport speeds and selects and stores one corresponding digital filter from the plurality of digital filters for each of the plurality of transport speeds.

According to this weighing device, the control unit has a plurality of digital devices for each of the plurality of transport speeds when the transport unit is in operation and the article is not transported by the transport unit (so-called idle operation). Select and store one of the corresponding digital filters. This makes it possible to automatically select a digital filter suitable for the measuring device and its surrounding conditions (for example, vibration of the measuring device itself, vibration transmitted from the outside to the measuring device, etc.). In addition, even if the transport speed of the article by the transport unit is changed during the weighing of the article by the weighing device, the digital filter suitable for the changed transport speed can be automatically selected. Therefore, for example, the weight of the article can be accurately weighed even if the designer of the weighing device does not respond every time the transport speed of the article is changed by the transport unit. Therefore, the weighing device can sufficiently exhibit the weighing performance while improving the work efficiency.

The weighing device may further include a display unit that displays a plurality of transport speeds and accuracy information for each of the plurality of transport speeds in association with each other. In this case, for example, when the operator tries to change the transport speed of the article by the transport unit, the difference in the weighing accuracy of the article at the transport speed before and after the change can be easily confirmed.

The control unit may calculate the accuracy information based on the standard deviation of the amplitude of the waveform obtained by filtering the original signal. In this case, the accuracy information can be easily calculated.

The control unit may calculate the accuracy information based on the standard deviation of the differential value of the amplitude of the waveform obtained by filtering the original signal. In this case, it is possible to calculate accuracy information that suppresses the influence of vibration generated when the article is conveyed to the weighing device.

The display unit may display a warning screen when the standard deviation corresponding to the specified transport speed exceeds a predetermined threshold value. In this case, the operator can easily exert the weighing performance of the weighing device sufficiently even at the changed transport speed.

The display unit may further display the weighing pitch of the article calculated by the transport speed, the dimensions of the article along the transport direction by the transport unit, and the transport frequency of the article. In this case, the operator can easily change the transport speed of the article by the transport unit within an appropriate range.

In the weighing device according to another aspect of the present invention, an article can be conveyed, an article is weighed on the conveying section, and the article is conveyed by the conveying section while the conveying section is in operation. When not, the control unit is provided to operate the transport unit at a plurality of transport speeds and acquire accuracy information corresponding to each of the plurality of transport speeds.

According to this measuring device, the control unit acquires accuracy information corresponding to each of a plurality of transport speeds when the transport unit is in operation and the article is not transported by the transport unit (so-called idle operation). do. As a result, the operator or the like can easily confirm the weighing accuracy of the article at each transport speed. Therefore, when changing the transport speed of the transport unit, it is easy to eliminate the transport speed having a relatively low weighing accuracy. Therefore, the determination of the transport speed can be expedited. In addition, the weighing accuracy of the article at the determined transport speed can be set to a high level. Therefore, the weighing device can sufficiently exhibit the weighing performance while improving the work efficiency.

According to one aspect of the present invention, it is possible to provide a weighing device capable of sufficiently exhibiting weighing performance while improving work efficiency.

FIG. 1 is a schematic configuration diagram of a weighing device according to an embodiment. FIG. 2 is a diagram showing a functional configuration of the control unit. FIG. 3 is a flowchart for explaining a method of selecting a digital filter. FIG. 4 is a diagram showing an example of a screen displayed by the display interface. FIG. 5A is a diagram showing a waveform included in the original signal. FIG. 5B is a diagram showing a waveform after filtering the waveform shown in FIG. 5A. FIG. 6A is an enlarged view showing a plurality of weighing results obtained by applying a default digital filter. FIG. 6B is an enlarged view showing a plurality of measurement results obtained by applying one digital filter different from the default digital filter. FIG. 7 is a schematic configuration diagram of the weighing device according to the first modification.

Hereinafter, embodiments according to one aspect of the present invention will be described in detail with reference to the drawings. In each figure, the same or corresponding parts are designated by the same reference numerals, and duplicate description will be omitted.

FIG. 1 is a diagram schematically showing a weighing device according to the present embodiment. The weighing device 1 shown in FIG. 1 is a device that weighs an object to be measured while transporting it in the direction of the arrow in FIG. 1 (hereinafter, simply referred to as “transportation direction”). The weighing device 1 is, for example, a device arranged on the final line of the production line. The object to be measured is, for example, an article P extending along the transport direction. The weighing device 1 includes a transport unit 2, a gantry 3, a measuring unit 4, and an operating unit 6.

The transport unit 2 is a transport device capable of transporting the article P along the transport direction, and is, for example, a conveyor. The transport unit 2 transports the article P at a designated transport speed, for example, via the operation unit 6. The transport speed is specified via the operation unit 6. The transport unit 2 includes a first conveyor unit 2a, a second conveyor unit 2b, and a third conveyor unit 2c. Each of the first conveyor unit 2a, the second conveyor unit 2b, and the third conveyor unit 2c has, for example, a roller, a rotating body such as a motor, a transport belt, and the like. The first conveyor section 2a, the second conveyor section 2b, and the third conveyor section 2c are arranged in order from the upstream side in the transport direction. That is, the second conveyor portion 2b is located between the first conveyor portion 2a and the third conveyor portion 2c in the transport direction. The first conveyor section 2a is a conveyor that carries the article P into the second conveyor section 2b. The first conveyor unit 2a may have, for example, a metal detector (not shown) or the like. The second conveyor section 2b is a conveyor that carries the article P conveyed from the first conveyor section 2a into the third conveyor section 2c. The third conveyor unit 2c is a conveyor that carries out the article P from the second conveyor unit 2b. The third conveyor unit 2c has, for example, a sorting machine (not shown) that sorts articles P whose weight deviates from an appropriate range.

The measuring unit 4 is mounted on the second conveyor unit 2b. Therefore, the article P transported by the transport unit 2 is weighed on the second conveyor unit 2b. Further, sensors for detecting the presence or absence of the article P may be provided on each of the upstream side and the downstream side of the second conveyor portion 2b. In this case, it can be easily determined whether or not the entire article P is located on the second conveyor portion 2b.

The gantry 3 is a member that accommodates the measuring unit 4, and is fixed to the floor F below the transport unit 2. The gantry 3 has a main body 3a for accommodating the measuring unit 4 and a plurality of legs 3b located between the main body 3a and the floor F. In FIG. 1, the main body 3a is shown by a broken line.

The measuring unit 4 is a measuring device that measures the weight of the article P located on the second conveyor unit 2b, and is located at the central portion of the transport unit 2. The measuring unit 4 includes a strain generating body 11 that receives compression and tension according to a load, and a measuring cell 12 that measures the article P located on the second conveyor unit 2b. The strain-causing body 11 has a movable rigid body portion 11a that supports the second conveyor portion 2b, and a fixed rigid body portion 11b that is fixed to the gantry 3. Each of the movable rigid body portion 11a and the fixed rigid body portion 11b is, for example, a member extending in the vertical direction. One end of the movable rigid body portion 11a is connected to the upstream end portion of the second conveyor portion 2b, and the other end of the movable rigid body portion 11a is connected to the measuring cell 12. One end of the fixed rigid body portion 11b is connected to the measuring cell 12, and the other end of the fixed rigid body portion 11b is connected to the main body 3a of the gantry 3. Although not shown, in the weighing cell 12, a plurality of strain gauges attached to the strain generating body 11 are connected to a Wheatstone bridge circuit.

In the present embodiment, the measuring unit 4 has an A / D conversion unit in addition to the strain generating body 11 and the measuring cell 12. The measuring cell 12 extracts an electric signal corresponding to the load transmitted from the strain generating body 11 from the Wheatstone bridge circuit. This electric signal is an analog original signal indicating the measurement result of the article P by the weighing cell 12, and is obtained when the article P is located on the second conveyor portion 2b. This analog original signal is converted into a digital original signal by the A / D conversion unit. The measuring unit 4 uses the digital original signal as the original signal and outputs it to the outside. As a result, the amount of data of the original signal transmitted from the measuring unit 4 to the operating unit 6 can be reduced.

The operation unit 6 is a member that operates the transport unit 2 and the measuring unit 4, and is erected in the vicinity of, for example, the second conveyor unit 2b. The operation unit 6 has a display interface 7 and a control unit 8.

The display interface 7 is a member (display unit) that displays an image based on the display information output from the control unit 8. The display interface 7 includes, for example, a measurement signal obtained by filtering the original signal, a measurement value indicating the measurement result of the weight of the article P, accuracy information for evaluating the accuracy of the measurement value, and a transfer speed of the transfer unit 2. , The size of the article P along the transport direction, the transport frequency of the article P, the weighing pitch of the article P, and the like are displayed. In the present embodiment, the display interface 7 has a touch panel 7a that functions as an external input unit. As a result, when the display interface 7 receives the input from the operator (user), the input information indicating the input content is output to the control unit 8. The input information is, for example, data regarding the transport speed of the transport unit 2, the dimensions of the article P along the transport direction, the type of the article P, the transport frequency of the article P, and the like. Each of the measurement value of the article P and the accuracy information is data obtained based on the original signal (more specifically, the measurement signal) transmitted from the measurement unit 4 to the operation unit 6. The measured value is calculated by a known method. Further, the weighing pitch of the article P is calculated by the control unit 8 based on the transfer speed of the transfer unit 2, the above-mentioned dimensions of the article P, and the transfer frequency of the article P. The transport frequency of the article P is set, for example, based on the capacity of the production machine located upstream of the weighing device 1.

The display interface 7 displays, for example, a plurality of transport speeds and accuracy information corresponding to each of the plurality of transport speeds. The plurality of transport speeds are, for example, the transport speed (designated transport speed) of the transport unit 2 designated via the touch panel 7a and the speed (change candidate speed) obtained by multiplying the designated transport speed by a predetermined value (margin value). ) And. The designated transport speed is, for example, the minimum speed (limit speed) for transporting the article P so that two or more articles P do not ride on the second conveyor portion 2b of the transport unit 2. The designated transport speed is calculated based on, for example, the transport frequency of the article P. By multiplying this limit speed by the margin value, the variation in the interval of the article P is allowed. Thereby, for example, the deviation of the supply timing of the article P generated upstream of the measuring device 1 can be absorbed. The margin value is, for example, 1.1 or more and 2 or less. For example, when the margin value is 1.25, the variation of the interval of the article P is allowed up to 25%. The conversion candidate speed is not limited to one speed. Therefore, the plurality of transport speeds include three or more transport speeds. The margin value may be less than 1.1 or less than 1. For example, when the production capacity of the weighing device 1 is intentionally reduced, the margin value is set to 1 or less.

In the present embodiment, the display interface 7 displays the plurality of transport speeds and the accuracy information for each of the plurality of transport speeds in association with each other. For example, the display interface 7 displays the designated transport speed and the accuracy information when the article P is weighed at the designated transport speed in association with each other. At this time, the designated transport speed and the accuracy information may be displayed on the display interface 7 at the same time, or may be displayed at different timings. In the former case, the designated transport speed and the above accuracy information may be enclosed in the same frame or the like. This may clarify the relationship with each other. In the latter case, for example, the above accuracy information may be displayed when the designated transport speed is selected. In addition, the display interface 7 displays a certain change candidate speed and the accuracy information when the article P is weighed at the change candidate speed in association with each other. At this time, the display interface 7 simultaneously displays at least the designated transport speed and the change candidate speed. The display interface 7 may display the accuracy information corresponding to each speed at the same time as each speed, or may display it at different timings.

The control unit 8 is a controller that controls each member included in the weighing device 1, and is built in the operation unit 6. The control unit 8 is composed of a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and the like. The control unit 8 outputs, for example, an operation signal for controlling the transfer speed of the transfer unit 2 designated via the display interface 7 to the transfer unit 2. Further, for example, when the distribution machine is provided in the third conveyor unit 2c and the control unit 8 determines that the weight of the article P deviates from a preset appropriate range, the control unit 8 Outputs an operation signal to the sorter so as to sort (exclude from the line) the article P. The control unit 8 is a processing unit that not only controls each member included in the weighing device 1 but also receives / calculates / transmits various signals and records / reads various signals. As an example of the calculation of various signals by the control unit 8, the derivation of the measurement result of the article P can be mentioned. Therefore, the control unit 8 is, for example, a drive circuit for outputting the control signal of the transport unit 2, a drive circuit for calculating the measurement value of the article P from the original signal generated by the measurement unit 4, and the original. It has a drive circuit for calculating the accuracy information from the signal, a storage circuit for storing each signal and each information, and the like.

When the article is not transported by the transport unit 2 while the transport unit 2 is in operation, the control unit 8 operates the transport unit 2 at a plurality of transport speeds, and a plurality of transport units 8 are operated for each of the plurality of transport speeds. Select and store one of the corresponding digital filters among the digital filters. Further, the control unit 8 operates the transport unit 2 at a plurality of transport speeds when the article is not transported by the transport unit 2 while the transport unit 2 is operating, and the accuracy corresponding to each of the plurality of transport speeds. Get information.

FIG. 2 is a diagram showing a functional configuration of the control unit. As shown in FIG. 2, the control unit 8 includes a reception unit 21, a filter unit 22, a calculation unit 23, an output unit 24, and a storage unit 25.

The receiving unit 21 is, for example, a part that receives the original signal transmitted from the measuring unit 4 and the input information transmitted from the display interface 7. The transmission of the original signal from the measuring unit 4 to the receiving unit 21 and the transmission of the input information from the display interface 7 to the receiving unit 21 may be performed via wire or wirelessly, respectively. You may. The receiving unit 21 may receive data other than the original signal and the input information.

The filter unit 22 is a unit that filters the original signal output from the measuring unit 4 by using a plurality of preset digital filters. Each of the plurality of digital filters is composed of a low-pass filter that attenuates frequency components exceeding a predetermined frequency, a notch filter (band stop filter) that attenuates frequency noise of a rotating body included in the transport unit 2, and the like. .. That is, when at least a part of the plurality of digital filters is selected, the filter unit 22 can perform multi-step filtering processing on the original signal. Each digital filter may include one or more low pass filters, one or more notch filters. Each of the plurality of digital filters may include a low-pass filter that attenuates different frequency bands from each other, or may include a notch filter that attenuates different frequency bands from each other. The plurality of low-pass filters may be, for example, the variable filter described in Japanese Patent No. 5901126.

The filter unit 22 filters the original signal by using one digital filter selected in advance from the plurality of digital filters during the operation of the transport unit 2 and the transport of the article P. Then, the filter unit 22 outputs a signal (measurement signal) obtained by filtering the original signal. The obtained measurement signal is output to, for example, a calculation unit 23, a storage unit 25, etc. included in the control unit 8 shown in FIG. The weighing signal has a waveform arranged to calculate the weight of the article P.

The filter unit 22 refers to the original signal obtained when the article P is not transported by the transport unit 2 during the operation of the transport unit 2 (hereinafter, also referred to as “idle operation of the transport unit 2”). Apply each of multiple digital filters. In other words, the filter unit 22 performs a filtering process in which each of the plurality of digital filters is applied to the original signal while the transport unit 2 is idle. As a result, the filter unit 22 generates a plurality of measurement signals that are the result of applying each of the plurality of digital filters to the original signal obtained during the idle operation of the transport unit 2. Then, the filter unit 22 outputs a plurality of measurement signals to the calculation unit 23, the storage unit 25, and the like. Whether or not the transport unit 2 is idle may be determined by the operator or may be automatically determined. For example, when the transport unit 2 is in operation and the non-detection state of the article detection sensor provided in the weighing device 1 continues for a predetermined time or longer, the transport unit 2 is automatically operated when it is idle. May be judged by.

In the present embodiment, the information output from the weighing unit 4 when the transport unit 2 is idle-operated at the designated transport speed input via the display interface 7 is multiplied by the margin value for the designated transport speed. Both the information output from the measuring unit 4 when the transport unit 2 is idle-operated at a speed is the source obtained when the transport unit 2 is operating and the article P is not transported by the transport unit 2. Corresponds to a signal. That is, when the information output from the weighing unit 4 when the transport unit 2 is idle-operated at a plurality of transport speeds is during the operation of the transport unit 2 and the article P is not transported by the transport unit 2. Corresponds to the obtained original signal. Therefore, the filter unit 22 applies each of the plurality of digital filters to the original signals obtained at each of the plurality of transport speeds to perform filtering processing.

For example, when a plurality of transport speeds have the first speed to the third speed, the first original signal to the third original signal are output from the measuring unit 4 during the idle operation of the transport unit 2. Here, for example, when a plurality of digital filters have a first filter to a third filter, each of the first original signal to the third original signal is filtered by each of the first filter to the third filter. implement. As a result, the first metric signal obtained by applying the first filter to the first original signal, the second metric signal obtained by applying the second filter to the first original signal, and the first metric signal. The third metric signal obtained by applying the third filter to the signal, the fourth metric signal obtained by applying the first filter to the second original signal, and the second filter to the second original signal. Obtained by applying the 5th metric signal obtained by applying, the 6th metric signal obtained by applying the 3rd filter to the 2nd original signal, and the 1st filter obtained by applying the 1st filter to the 3rd original signal. The 7th metric signal to be obtained, the 8th metric signal obtained by applying the 2nd filter to the 3rd original signal, and the 9th metric signal obtained by applying the 3rd filter to the 3rd original signal. Is obtained.

The calculation unit 23 is a part that performs calculation processing of various input information. The calculation unit 23 calculates and processes the weight of the article P based on the measurement signal output from the filter unit 22 during the operation of the transport unit 2 and the transport of the article P. As a result, the calculation unit 23 generates the measured value of the article P. The calculation unit 23 outputs the generated measurement value to the output unit 24. The calculation unit 23 calculates the measurement pitch (measurement interval) of the article P according to the set transfer speed of the transfer unit 2, the size of the article P, and the transfer frequency. Based on the measured value, the calculation unit 23 determines whether or not the weight of the article P deviates from the preset appropriate range. Depending on the determination result, the calculation unit 23 outputs an operation signal to, for example, a distributor.

A plurality of calculation units 23 are based on the result of applying each of a plurality of digital filters to the original signal obtained when the transport unit 2 is operating and the article P is not transported by the transport unit 2. Select one of the digital filters in. In the present embodiment, the calculation unit 23 first generates a plurality of accuracy information based on a plurality of measurement signals obtained during idle operation of the transport unit 2 at a set transport speed. Subsequently, the calculation unit 23 compares the plurality of accuracy information and determines the most appropriate accuracy information and / or the measurement signal. Subsequently, the calculation unit 23 selects a digital filter corresponding to the determined accuracy information and / or the measurement signal. Then, the calculation unit 23 outputs the determined accuracy information and / or the measurement signal and the information regarding the selected digital filter to the storage unit 25.

The accuracy information is calculated based on, for example, the standard deviation of the amplitude of the waveform contained in the metric signal obtained by filtering the original signal. The calculation result may be the standard deviation of the amplitude of the waveform itself. In this embodiment, the accuracy information is the standard deviation of the amplitude of the waveform included in the measurement signal. Therefore, the calculation unit 23 compares the standard deviations of the amplitudes for each waveform obtained by applying each of the plurality of digital filters to the original signal, and selects the digital filter that obtains the smallest standard deviation. In addition, the calculation unit 23 selects a digital filter that obtains the smallest standard deviation at each of the plurality of transport speeds.

For example, when the transport speed is set to the first speed and a plurality of digital filters have the first filter to the third filter, the calculation unit 23 sets the first standard deviation of the amplitude of the waveform included in the first measurement signal and the second. The second standard deviation of the amplitude of the waveform included in the measurement signal and the third standard deviation of the amplitude of the waveform included in the third measurement signal are calculated. Subsequently, the calculation unit 23 identifies the measurement signal from which the smallest value is obtained from the first standard deviation, the second standard deviation, and the third standard deviation. Then, the calculation unit 23 selects the digital filter applied by the measurement signal specified at the first speed. Further, when the transport speed is set to the second speed, the calculation unit 23 uses the fourth standard deviation of the amplitude of the waveform included in the fourth measurement signal and the fifth standard deviation of the amplitude of the waveform included in the fifth measurement signal. And the sixth standard deviation of the amplitude of the waveform included in the sixth measurement signal are calculated. Subsequently, the calculation unit 23 identifies the measurement signal from which the smallest value is obtained from the fourth standard deviation, the fifth standard deviation, and the sixth standard deviation. Then, the calculation unit 23 selects the digital filter applied by the measurement signal specified at the second speed. The digital filter selected at the first speed and the digital filter selected at the second speed may be the same as each other or may be different from each other.

The waveform included in the measurement signal includes vibration generated by the measurement device 1 and its surroundings. The vibration becomes noise with respect to the weighing of the article P. Therefore, it can be determined that the smaller the standard deviation of the amplitude of the waveform, the smaller the noise with respect to the weighing of the article P. The vibration generated by the measuring device 1 is vibration caused by the operation of the transport unit 2, vibration generated when the article P is transported to the transport unit 2, and the like. The vibration generated around the measuring device 1 is, for example, vibration transmitted from the floor surface on which the measuring device 1 is placed (floor vibration) or the like. The floor vibration is, for example, vibration caused by a device installed on a production line of an article P including a measuring device 1, a device not included in the production line, or the like.

The output unit 24 outputs, for example, various information and various signals generated by the control unit 8 and various information and various signals stored in the storage unit 25 to the outside. The output unit 24 outputs, for example, the measurement signal, the measurement value, the accuracy information, the measurement pitch, and the like of the article P to the display interface 7 as display information. The output unit 24 outputs an operation signal for controlling the transfer speed of the transfer unit 2 to the transfer unit 2, and outputs an operation signal for the distributor to the distributor. The output of the operation signal from the output unit 24 to the transport unit 2 may be performed via wire or wirelessly.

The storage unit 25 stores the input information input via the display interface 7 and various information and various signals generated by the control unit 8. The storage unit 25 stores a plurality of preset digital filters. The storage unit 25 sets the date and time when one of the plurality of digital filters is selected based on the result of applying each of the plurality of digital filters to the original signal obtained during the idle operation of the transport unit 2. Remember. At this time, the date and time when one of the plurality of digital filters is selected is stored for each of the plurality of original signals obtained during the idle operation of the transport unit 2. In addition, the storage unit 25 stores the one digital filter selected at the date and time, the original signal itself, the measurement signal based on the original signal, and the accuracy information at each of the plurality of transport speeds. As a result, the operator can easily confirm the weighing status of the weighing device 1 when the above-mentioned one digital filter is selected.

Next, a method of automatically selecting a digital filter by the weighing device 1 according to the present embodiment will be described with reference to FIG. FIG. 3 is a flowchart for explaining a method of selecting a digital filter.

First, the transport speed of the transport unit 2 is determined (step S1). In step S1, the transfer speed of the transfer unit 2 is specified via the display interface 7. At this time, the operator may input the transport speed itself of the transport unit 2 via the display interface 7, or may input the transport frequency of the article P. In the latter case, the control unit 8 calculates the transfer speed of the transfer unit 2.

Next, the original signal when the transport unit 2 is operated in a state where the article P is not transported (that is, when the transport unit 2 is idled) is acquired (step S2). In step S2, for example, the weighing unit 4 acquires the original signal when the transport unit 2 is idle-operated for about 5 seconds at a designated transport speed before weighing the article P. The acquired original signal is output to the control unit 8.

Next, each of the plurality of digital filters is applied to the acquired original signal (step S3). In step S3, the filter unit 22 applies each of the plurality of digital filters to the original signal to perform filtering processing. As a result, the filter unit 22 generates a plurality of measurement signals.

Next, the standard deviations of the amplitudes of each waveform after the filtering process are compared (step S4). In step S4, first, the calculation unit 23 calculates the standard deviation of the amplitude of the waveform included in each of the plurality of measurement signals. Subsequently, the calculation unit 23 compares the magnitude of each standard deviation. Here, the calculation unit 23 determines the waveform from which the smallest standard deviation is obtained among the plurality of standard deviations.

Next, one of the plurality of digital filters is selected (step S5). In step S5, the calculation unit 23 selects the digital filter used to generate the metric signal having the waveform with the smallest standard deviation. The selected digital filter may be a digital filter used in the standard setting (default digital filter) among a plurality of digital filters, or a digital filter different from the default digital filter. In other words, as a result of performing steps S1 to S5, the default digital filter used in the standard setting may be continuously selected, or a digital filter different from the default digital filter may be selected. As described above, the digital filter used when the article P is weighed at the designated transport speed is automatically set and reserved before the article P is weighed.

Next, the transport unit 2 is idle-operated at a transport speed obtained by multiplying the designated transport speed by the margin value. Then, after performing the above steps S2 during this idle operation, the above steps S3 to S5 are carried out in order. That is, the above steps S2 to S5 are executed again at a transport speed different from the designated transport speed. In this way, steps S2 to S5 are performed each time the transport speed is changed. As a result, the control unit 8 operates the transport unit 2 at a plurality of transport speeds while the transport unit 2 is idle, and for each of the plurality of transport speeds, one of the plurality of digital filters corresponds to one digital filter. Select and memorize. More specifically, the control unit 8 has a plurality of control units 8 based on the result of applying each of the plurality of digital filters to the original signals obtained at each of the plurality of transport speeds while the transport unit 2 is idle. One of a plurality of digital filters is selected and stored for each of the transport speeds. As described above, for example, before weighing the article P, the digital filter used when the article P is weighed at each of the plurality of transport speeds is automatically set and reserved. Then, the control unit 8 operates the transport unit 2 at a plurality of transport speeds while the transport unit 2 is idle, and acquires and stores accuracy information corresponding to each of the plurality of transport speeds.

Next, an example of a method of designating the transport speed of the transport unit 2 of the weighing device 1 will be described with reference to FIG. FIG. 4 is a diagram showing an example of a screen displayed by the display interface 7. As shown in FIG. 4, at least a part of the display interface 7 displays a graph showing a plurality of transport speeds and accuracy information obtained by filtering the original signals corresponding to each of the plurality of transport speeds. indicate. The vertical axis of the graph indicates the magnitude of the standard deviation of the amplitude of the waveform corresponding to the accuracy information. The horizontal axis of the graph indicates the magnification to be multiplied by the designated transport speed. “0%” shown in FIG. 4 corresponds to the designated transport speed. That is, "0%" indicates that the specified transport speed is not multiplied by the margin value. “10%” shown in FIG. 4 indicates that the specified transport speed is multiplied by the margin value “1.1”. That is, "10%" indicates that the designated transport speed has increased by 10%. Similarly, “25%” shown in FIG. 4 indicates that the specified transport speed is multiplied by the margin value “1.25”.

As shown in FIG. 4, it can be seen that the larger the margin value, the larger the standard deviation tends to be. As described above, the smaller the standard deviation, the higher the weighing accuracy of the weighing device 1. Here, the display interface 7 shows the standard deviation of the amplitude of the waveform at each of the plurality of transport speeds. Therefore, the operator who knows the display interface 7 can easily confirm the weighing accuracy of the weighing device 1 at each of the plurality of transport speeds. Therefore, the operator can easily select the transport speed within the range of good weighing accuracy via the touch panel 7a. For example, when the operator operates the operation unit displayed on the display interface 7, the transfer unit 2 operates at a desired transfer speed. That is, the operator can specify the transport speed of the transport unit 2 via the touch panel 7a, which is an input unit, while referring to the figure displayed on the display interface 7. The operation unit may overlap the screen displayed on the display interface 7. In this case, for example, the operator can set or change the transport speed of the transport unit 2 by touching a portion showing a margin value on the display interface 7. As a result, the operator can easily operate the transport unit 2 at a transport speed according to the selected margin value. At this time, a digital filter corresponding to the transport speed is selected.

In the present embodiment, the storage unit 25 stores the standard deviation of the amplitude of the waveform serving as the threshold value. The control unit 8 compares the stored threshold value with the standard deviation corresponding to the transfer speed specified via the input unit. When the standard deviation exceeds the threshold value, the display interface 7 displays a warning screen under the control of the control unit 8. The operator can reexamine whether or not the article P is weighed by the weighing device 1 with a relatively low weighing accuracy. The operator may cancel the warning screen by withdrawing the designation of the transport speed or designating another transport speed. Alternatively, the operator may continue to operate the transport unit 2 at the designated transport speed after canceling the warning screen.

The display interface 7 can display the screen shown in FIG. 4, for example, even after the weighing device 1 has started weighing the article P. In other words, the display interface 7 provides, for example, a plurality of transport speeds and a weighing signal and / or accuracy information corresponding to each of the plurality of transport speeds even after the weighing device 1 starts weighing the article P. Can be displayed.

Next, the effects exerted by the measuring device 1 according to the present embodiment will be described with reference to FIGS. 5 and 6. FIG. 5A is a diagram showing a waveform included in the original signal. FIG. 5B is a diagram showing a waveform after filtering the waveform shown in FIG. 5A.

FIG. 5A shows a waveform 51 for calculating the weight of the article P acquired by the weighing unit 4 of the weighing device 1 when the transporting unit 2 is transported at a predetermined speed. The waveform includes noise and the like caused by the measuring device 1 and its surroundings. Therefore, usually, the noise is removed by performing a filtering process on the waveform.

FIG. 5B shows waveforms 52 and 53 after filtering the waveform 51. The waveform 52 is a waveform obtained by applying a digital filter (default digital filter) used in a standard setting among a plurality of digital filters. The waveform 53 is a waveform obtained by applying one of a plurality of digital filters different from the default digital filter. According to FIG. 5B, the noise of the waveform 53 tends to be removed more than that of the waveform 52. Therefore, when the weighing device 1 weighs the article P at the predetermined speed, it is estimated that the weight of the article P is accurately weighed by applying the one digital filter rather than the default digital filter. Will be done.

In order to confirm the above estimation, the measurement results of a plurality of articles P will be compared and examined below. FIG. 6A is an enlarged view showing a plurality of weighing results obtained by applying a default digital filter. FIG. 6B is an enlarged view showing a plurality of measurement results obtained by applying one digital filter different from the default digital filter. As shown in FIGS. 6A and 6B, the amplitudes of the plurality of waveforms are smaller when the above-mentioned one digital filter is applied than when the default digital filter is applied. .. Therefore, the standard deviation of the amplitude of the waveform is also smaller when the above-mentioned one digital filter is applied. Therefore, when the weighing device 1 weighs the article P at the predetermined speed, the weighing device 1 is used more when the one digital filter is applied than when the default digital filter is applied. It can be seen that the weighing performance can be fully exhibited.

Further, when the transport speed of the weighing device 1 is changed, the vibration of the weighing device 1 may change. In addition, for example, when the production amount of the article P by the production line of the article P including the weighing device 1 is changed, the transport speed of not only the measuring device 1 but also other devices is reset. In these cases, not only the vibration caused by the measuring device 1 but also the vibration caused by other devices changes. Therefore, for example, a digital filter selected at a predetermined transport speed is not always the optimum filter at a transport speed other than the predetermined transport speed. Therefore, it is necessary to reselect the optimum digital filter in order to sufficiently exhibit the weighing performance of the weighing device 1 even after the transfer speed of the measuring device 1 is changed. This reselection of the digital filter imposes a heavy burden on skilled workers, designers, and the like of the weighing device 1.

Here, according to the weighing device 1 according to the present embodiment, the control unit 8 corresponds to one of the plurality of digital filters for each of the plurality of transport speeds when the transport unit 2 is idle. Select and memorize. Thereby, a digital filter suitable for the measuring device 1 and its surroundings (for example, vibration of the measuring device 1 itself, vibration transmitted from the outside to the measuring device 1 and the like) can be automatically selected. In addition, even if the transport speed of the article P by the transport unit 2 is changed via the touch panel 7a during the weighing of the article P by the weighing device 1, the digital filter suitable for the changed transport speed is automatically used. Be selected. Therefore, for example, the weight of the article P can be accurately weighed even if the designer of the weighing device 1 does not respond every time the conveying speed of the article P is changed by the conveying unit 2. Therefore, the weighing device 1 can sufficiently exhibit the weighing performance while improving the work efficiency.

In addition, the control unit 8 acquires accuracy information corresponding to each of the plurality of transport speeds when the transport unit 2 is idle. As a result, the operator or the like can easily confirm the weighing accuracy of the article at each transport speed. Therefore, when the transport speed of the transport unit 2 is changed, it becomes easy to eliminate the transport speed having a relatively low weighing accuracy. Therefore, the determination of the transport speed can be expedited. In addition, the weighing accuracy of the article at the determined transport speed can be set to a high level. Therefore, for this reason as well, the weighing device 1 can sufficiently exhibit the weighing performance while improving the work efficiency.

In the present embodiment, the weighing device 1 includes a display interface 7 that displays a plurality of transport speeds and accuracy information for each of the plurality of transport speeds in association with each other. Therefore, for example, when the operator tries to change the transport speed of the article P by the transport unit 2, it is possible to easily confirm the difference in the weighing accuracy of the article P at the transport speed before and after the change.

In the present embodiment, the calculation unit 23 of the control unit 8 calculates the accuracy information based on the standard deviation of the amplitude of the waveform obtained by filtering the original signal. Therefore, the calculation unit 23 can easily calculate the accuracy information.

In the present embodiment, the display interface 7 displays a warning screen when the standard deviation corresponding to the transport speed specified from the outside exceeds a predetermined threshold value. Therefore, the operator can easily exert the weighing performance of the weighing device 1 sufficiently even at the changed transport speed.

In the present embodiment, the display interface 7 may display the measurement pitch of the article P calculated by the transport speed, the dimension of the article P along the transport direction by the transport unit 2, and the transport frequency of the article P. In this case, the operator can easily change the transport speed of the article P by the transport unit 2 within an appropriate range.

Hereinafter, a modified example of the above embodiment will be described. In the following modification, the description of the portion overlapping with the above embodiment will be omitted. Therefore, in the following, the parts different from the above-described embodiment will be mainly described.

FIG. 7 is a schematic configuration diagram of the weighing device according to the first modification. As shown in FIG. 7, the weighing device 1A is a device for measuring the weight of the long article P1 along the transport direction, and has a first measuring unit 4A and a second measuring unit 5. The first measuring unit 4A is located on the upstream side of the second conveyor unit 2b. The second measuring unit 5 is located on the downstream side of the second conveyor unit 2b and has a strain generating body 31 and a measuring cell 32. Like the strain-causing body 11, the strain-causing body 31 has a movable rigid body portion 31a that supports the second conveyor portion 2b and a fixed rigid body portion 31b that is fixed to the gantry 3.

During idle operation of the transport unit 2, the filter unit 22 of the control unit 8 has, for example, the 11th original signal output from the 1st measurement unit 4A and the 21st original signal output from the 2nd measurement unit 5, respectively. On the other hand, one of a plurality of digital filters is selected. In this case, the digital filter selected based on the 11th original signal and the digital filter selected based on the 21st original signal may be the same as each other or may be different from each other. In this case, the measurement signal obtained by filtering the measurement signal output from the first measurement unit 4A while the transfer unit 2 is operating and the article P is being conveyed by the transfer unit 2 and the measurement signal obtained from the second measurement unit 5 The output measurement signal is added up with the measurement signal obtained by filtering. Based on the total weighing signal obtained thereby, the control unit 8 generates the weighing value of the article P.

Alternatively, the filter unit 22 of the control unit 8 may, for example, refer to the total original signal of the 11th original signal output from the 1st measurement unit 4A and the 21st original signal output from the 2nd measurement unit 5. Select one of the multiple digital filters. In this case, the control unit 8 first adds up the 11th original signal output from the 1st measuring unit 4A and the 21st original signal output from the 2nd measuring unit 5 during the idle operation of the transport unit 2. Generates the total original signal. Then, the calculation unit 23 selects one of the plurality of digital filters for the total original signal. In this case, the weighing signal output from the first weighing unit 4A and the weighing signal output from the second weighing unit 5 are added up while the transporting unit 2 is operating and the article P is being transported by the transporting unit 2. .. Based on the measurement signal obtained by filtering the total measurement signal obtained in this manner, the control unit 8 generates the measurement value of the article P.

In the first modification, similarly to the above embodiment, the transport unit 2 of the weighing device 1A runs idle at a plurality of transport speeds including the designated transport speed. Then, the control unit 8 selects one digital filter for each of the plurality of transport speeds.

The measuring device 1A according to the first modification also has the same effects as those in the above embodiment. In addition, according to the first modification, the weight of the long article P1 can be accurately measured along the transport direction.

Although the embodiment of the measuring device and its modification according to one aspect of the present invention have been described above, one aspect of the present invention is not limited to the above embodiment and the above modification.

In the above embodiment and the above modification, the accuracy information is calculated based on the standard deviation of the amplitude of the waveform obtained by applying the digital filter to the original signal, or the standard deviation, but is not limited thereto. .. For example, the accuracy information may be the standard deviation of the differential value of the amplitude of the waveform obtained by applying a digital filter to the original signal, or may be calculated based on the standard deviation. In this case, the influence of vibration generated when the article is conveyed to the weighing device can be reduced. Therefore, it becomes easier to automatically select a digital filter suitable for the weighing device and its surroundings. Alternatively, the accuracy information may be the standard deviation of the second derivative of the amplitude of the waveform obtained by applying a digital filter to the original signal, or may be calculated based on the standard deviation.

In the above embodiment and the above modification, the measuring unit uses the digital signal as the original signal and outputs it to the outside, but the present invention is not limited to this. The measuring unit may output the acquired analog signal to the outside. In this case, for example, the control unit may digitally convert the analog signal.

In the above embodiment and the above modification, the display interface of the weighing device displays the weighing signal, the transport speed, the accuracy information, and the like, but the present invention is not limited to this. For example, a mobile device or the like that has received the information output from the weighing device may display the transport speed or the like. In this case, the transport speed or the like of the transport unit may be changed via the portable device or the like. Further, in the above-described embodiment and the above-described modification, the input information is input via the display interface, but the present invention is not limited to this.

In the above-described embodiment and the above-described modification, after selecting the digital filter corresponding to the specified transport speed, the digital filter corresponding to the speed obtained by multiplying the designated transport speed by the margin value is selected, but the present invention is not limited to this. .. For example, a digital filter corresponding to a speed obtained by multiplying a specified transport speed by a margin value may be selected, and then a digital filter in which the margin value is changed may be selected. In this case, the digital filter corresponding to the speed indicating "0%" can be selected by including 1 in the margin value.

In the above-described embodiment and the above-described modification, the digital filters corresponding to each of the plurality of transport speeds are selected before weighing the article, but the present invention is not limited to this. For example, only digital filters corresponding to one transport speed may be selected before weighing the article. In this case, for example, when changing the transport speed of the transport unit after weighing the article, steps S2 to S5 may be performed for a transport speed different from the transport speed of 1. That is, among the plurality of transport speeds, the selection of the digital filter corresponding to a part of the transport speeds and the selection of the digital filter corresponding to some other transport speeds may be performed at different timings.

In the above embodiment and the above modification, when the standard deviation exceeds a predetermined threshold value, the display interface displays a warning screen by the control of the control unit, but the present invention is not limited to this. For example, if the standard deviation exceeds a predetermined threshold, the control unit may not accept the setting and change to the specified transport speed. That is, the control unit may prohibit setting and changing to a part of the plurality of transport speeds. In this case, it is possible to easily prevent the article P from being weighed at a transport speed having a low weighing accuracy.

1,1A ... Weighing device, 2 ... Conveying unit, 3 ... Stand, 4 ... Weighing unit, 4A ... First measuring unit, 5 ... Second weighing unit, 6 ... Operation unit, 7 ... Display interface, 8 ... Control unit, 11, 31 ... Distortion body, 11a, 31a ... Movable rigid body, 11b, 31b ... Fixed rigid body, 12, 32 ... Weighing cell, 21 ... Receiver, 22 ... Filter, 23 ... Calculation, 24 ... Output , 25 ... Memory, P ... Goods.

Claims (7)

A transport unit that can transport goods and
A measuring unit that weighs the article on the transport unit, and a measuring unit that weighs the article.
When the article is not transported by the transport unit during the operation of the transport unit, the transport unit is operated at a plurality of transport speeds, and for each of the plurality of transport speeds, a plurality of digital filters are used. It is equipped with a control unit that selects and stores one of the corresponding digital filters.
Weighing device. The weighing device according to claim 1, further comprising a display unit that displays the plurality of transport speeds and accuracy information for each of the plurality of transport speeds in association with each other. The weighing device according to claim 2, wherein the control unit calculates the accuracy information based on the standard deviation of the amplitude of the waveform obtained by filtering the original signal output from the measuring unit. The weighing device according to claim 2, wherein the control unit calculates the accuracy information based on the standard deviation of the differential value of the amplitude of the waveform obtained by filtering the original signal output from the measuring unit. The weighing device according to claim 3 or 4, wherein the display unit displays a warning screen when the standard deviation corresponding to the designated transport speed exceeds a predetermined threshold value. Any of claims 2 to 5, wherein the display unit further displays the measurement pitch of the article calculated by the transport speed, the dimensions of the article along the transport direction by the transport unit, and the transport frequency of the article. The weighing device according to one item. A transport unit that can transport goods and
A measuring unit that weighs the article on the transport unit, and a measuring unit that weighs the article.
Control to operate the transport unit at a plurality of transport speeds and acquire accuracy information corresponding to each of the plurality of transport speeds when the transport unit is in operation and the article is not transported by the transport unit. With a department,
Weighing device.

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